Switch device

ABSTRACT

A switch device includes a knob member rotatably fitted to and supported by a middle serving as a fixing portion, and a rotor member integrally mounted to the knob member and rotatably supported by the middle. A rotation regulating portion that regulates a rotatable range of the knob member with respect to the middle and rotation sliding surfaces in a rotational axis direction of the middle and the knob member are collectively formed.

The present application is based on Japanese patent application No. 2015-035194 filed on Feb. 25, 2015, the entire contents of which are incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a switch device.

2. Description of the Related Art

Conventional switch devices include a composite switch device for an automobile provided to a steering column of a vehicle. In such a device, a rotary light switch knob driven to switch a light switch, and a rotary fog switch knob driven to turn on a fog light switch are rotatably supported on a lever shaft and an outer cylindrical shaft, respectively (Patent Document 1, for example).

In the switch device of Patent Document 1, the light switch knob is rotatably fitted and assembled to a fixing portion. An angle in a peripheral direction of an interfering hole serving as a rotation stopper provided to the fixing portion is configured to match a sum of an angle in a circular direction of a connecting projection of the light switch knob and a rotation angle of the light switch knob.

CITATION LIST Patent Literature

Japanese Unexamined Patent Application Publication No. H09-198968A

SUMMARY OF THE INVENTION

In the switch device of Patent Document 1, the rotation stopper that regulates a relative rotation angle of the light switch knob with respect to the fixing portion includes the connecting projection of the light switch knob and the interfering hole as a rotation stopper provided to the fixing portion as described above, and is provided separately from a sliding surface in the rotational axis direction of the light switch knob and the fixing portion. As a result, the problem may arise that there is insufficient design flexibility in a limited space.

An object of the present invention is to provide a switch device that, in a configuration including a rotation mechanism of a rotor member and a fixing portion, integrally includes a rotation regulating portion and rotation sliding surfaces, thereby achieving excellent design flexibility even in a limited space.

[1] According to an embodiment of the invention, provided is a switch device including a knob member rotatably fitted to and supported by a fixing portion, and a rotor member integrally mounted to the knob member and rotatably supported by the fixing portion. A rotation regulating portion that regulates a rotatable range of the knob member with respect to the fixing portion and a rotation sliding surface in a rotational axis direction of the fixing portion and the knob member are collectively formed.

[2] The switch device may be the device described in [1] above, wherein the rotation sliding surface of the fixing portion is formed on a lower portion of the rotation regulating portion of the fixing portion.

[3] Further, the switch device may be the device described in [1] or [2] above, wherein the rotation sliding surface of the knob member is formed on an end surface of a flange portion of the knob member.

[4] According to another embodiment of the invention, provided is a switch device comprising a knob member rotatably around a rotational axis fitted to and supported by a fixing portion, and a rotor member integrally mounted to the knob member and rotatably around the rotational axis supported by the fixing portion, wherein the fixing portion comprises a rotation regulating portion that regulates a rotatable range of the rotor member, and a rotation sliding surface that contacts with the knob member when the rotor member is rotated with respect to the fixing member.

[5] Further, the switch device may be the device described in [4] above, wherein the rotation regulating portion comprises a contact surface formed substantially in a radial direction of the rotational axis, and wherein the contact surface is substantially orthogonal to the rotation sliding surface.

[6] Further, the switch device may be the device described in [4] or [5] above, wherein the rotation regulating portion and the rotation sliding surface are formed outside the knob member in a radial direction of the rotational axis.

Advantageous Effects of Invention

According to an embodiment of the present invention, it is possible to provide a switch device that, in a configuration including a rotation mechanism of a rotor member and a fixing portion, integrally includes a rotation regulating portion and rotation sliding surfaces, thereby achieving excellent design flexibility even in a limited space.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an exploded perspective view illustrating an overall configuration of a switch device according to an embodiment of the present invention.

FIG. 2A is a longitudinal cross-sectional view that includes a longitudinal axis CL of the switch device according to the embodiment of the present invention.

FIG. 2B is a transverse cross-sectional view illustrating the cross section A-A in FIG. 2A.

FIG. 3 is a longitudinal cross-sectional view of a subassembled state of a distal end knob, a middle, an intermediate knob, and detent components of the switch device according to the embodiment of the present invention.

FIG. 4A is a transverse cross-sectional view illustrating the cross section B-B in FIG. 3.

FIG. 4B is a transverse cross-sectional view illustrating the cross section C-C in FIG. 3.

FIG. 5 is a cross-sectional view of the cross-section D-D in FIG. 1, illustrating an assembled state of a lever main body, a movable contact member, a flexible substrate, and a lever cover.

FIG. 6 is a partial cross-sectional view of the switch device according to the embodiment of the present invention mounted to a vehicle, illustrating water droplets dripping from above.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiment(s) of Present Invention Configuration of Switch Device 1

FIG. 1 is an exploded perspective view illustrating an overall configuration of a switch device according to an embodiment of the present invention. This switch device 1 is mounted to a steering column of a vehicle and is for operating in-vehicle turn signal lamps, headlamps, and fog lamps. The switch device 1 is configured as follows. This switch device is described in the following as a device applied to a turn lever device of a vehicle, and as a configuration for a left-hand drive vehicle. The switch device 1 configured as illustrated in FIG. 1 is mounted to the steering column, and is pivotable between a neutral position and a right-turn position on an upper side from the neutral position, and between the neutral position and a left-turn position on a lower side from the neutral position. Further, the switch device 1 is capable of performing control such as turning on the lights on the basis of a rotational operation of a cap 60, and turning on the fog lights on the basis of a rotational operation of an intermediate knob 30.

The switch device 1 according to the embodiment of the present invention includes: rotor members (cam 20, cap 60) mounted so as to be rotatable about a longitudinal axis CL of a lever main body 10, the rotor members (cam 20, cap 60) including cam surfaces; knob members (intermediate knob 30, distal end knob 50) mounted so as to be integrally rotatable with the rotor members (cam 20, cap 60), the knob members (intermediate knob 30, distal end knob 50) including cam surfaces that face the cam surfaces of the rotor members (cam 20, cap 60) with a gap therebetween; movable contact members (first movable contact member 130, second movable contact member 140) disposed in a gap between the cam surfaces of the rotor members (cam 20, cap 60) and the cam surfaces of the knob members (intermediate knob 30, distal end knob 50), the movable contact members (first movable contact member 130, second movable contact member 140) being movable in the longitudinal axis CL direction by a rotational operation of the rotor members (cam 20, cap 60) and the knob members (intermediate knob 30, distal end knob 50) about the longitudinal axis CL; and a flexible substrate 70 linearly disposed in the longitudinal axis CL direction in at least a movable range of the movable contact members (first movable contact member 130, second movable contact member 140), the flexible substrate 70 including contact portions (signal contacts 71 a, ground contact 71 b), contact terminals (133, 143) of the movable contact members (first movable contact member 130, second movable contact member 140) being brought into contact with and separated from the contact portions in association with a movement in the longitudinal axis CL direction of the contact terminals (133, 143). The longitudinal axis CL serves as a rotational axis of the rotor members (cam 20, cap 60) and the knob members (intermediate knob 30, distal end knob 50) described above.

In the above-described configuration, the switch device 1 includes the knob member (distal end knob 50) rotatably fitted to and supported by a middle 40 serving as the fixing portion, the rotor member (cap 60) integrally mounted to the knob member (distal end knob 50) and rotatably supported by the middle 40, a rotation regulating portion that regulates the rotatable range of the knob member (distal end knob 50) with respect to the middle 40, and rotation sliding surfaces in the rotational axis (longitudinal axis CL) direction of the middle 40 and the knob member (distal end knob 50), the rotation regulating portion and the rotation sliding surfaces being integrally formed together. Here, “collectively formed” means that the rotation regulating portion and the rotation sliding surfaces are formed closely positioned to each other.

It should be noted that the intermediate knob 30, the middle 40, the distal end knob 50, as well as first springs 110, first balls 111, second springs 120, and second balls 121 serving as detent components illustrated in FIG. 1 are temporarily assembled into a single piece in a process before incorporation into the switch device 1, and incorporated into the switch device 1 as a subassembly 100.

Lever Main Body 10

The lever main body 10, which serves as a base member into which each member illustrated in FIG. 1 is incorporated, is formed of a synthetic resin, for example. Each member is formed of a synthetic resin unless otherwise limited in the following. The lever main body 10, as illustrated in FIG. 1, is formed in a lever shape of a base portion 11 into which the rotor members (cam 20, cap 60), the knob members (intermediate knob 30, distal end knob 50), and the like are incorporated; a lever shaft portion 12 disposed on the steering column side and including a rotating central shaft for a lever function, and the like formed therein; and an intermediate portion 13.

The base portion 11 has a substantially cylindrical shape to which the rotor members (cam 20, cap 60) and the knob members (intermediate knob 30, distal end knob 50) are fitted so as to be rotatable about the longitudinal axis CL. The base portion 11 includes a circumferential portion 11 a that rotatably supports the rotor members (cam 20, cap 60) and the knob members (intermediate knob 30, distal end knob 50) on an outer circumferential portion of the cylindrical shape, and a flat portion 11 b formed in parallel with the longitudinal axis CL. A space portion 11 c, which is a hollow portion, housing the flexible substrate 70 is formed inside the cylindrical shape (refer to FIG. 5). Further, a flange portion 11 d that comes into contact with an end surface of the cam 20 in the longitudinal axis CL direction is formed on the intermediate portion 13 side.

In the space portion 11 c, a long guide hole 11 e is formed so as to house the flexible substrate 70 and to allow the signal contacts 71 a and the ground contact 71 b of the flexible substrate 70 to be exposed on the first movable contact member 130 and the second movable contact member 140 side. This long guide hole 11 e is formed at two locations and is capable of supporting the first movable contact member 130 and the second movable contact member 140 so that each is slidable in the longitudinal axis CL direction. Further, to incorporate the first movable contact member 130 and the second movable contact member 140, an incorporation hole 11 f having a width larger than the width of the long guide hole 11 e is formed on an end portion of each of the long guide holes 11 e.

Further, to press and fix the flexible substrate 70 to the base portion 11, a locking hole 11 g for locking a fixing catch portion 81 a of a lever cover 80 is formed as illustrated in FIGS. 1 and 5.

Further, a locking hole 11 h for fixing the middle 40 to the lever main body 10 and mounting a knob structure including the subassembly 100, the cam 20, and the cap 60 to the lever main body 10 is formed as illustrated in FIG. 1.

Cam 20

The cam 20 is equivalent to the rotor member. The cam 20 is formed in a cylindrical shape having an inner circumference portion that rotatably is fitted to the circumferential portion 11 a of the base portion 11. A cam portion 20 b is formed on an end surface opposite to an end surface 20 a that comes into contact with the flange portion 11 d of the base portion 11. This cam portion 20 b is formed so as to have an inclined surface that inclines with respect to the longitudinal axis CL. Further, a projection portion 20 c for fitting and integrating the cam 20 with the intermediate knob 30 is formed at two locations on the cam portion 20 b side of the cam 20.

Intermediate Knob 30

The intermediate knob 30 is equivalent to the knob member. The intermediate knob 30 is formed in a cylindrical shape, integrated with the cam 20 by a fitting recess portion 30 e being fitted to the projection portion 20 c of the cam 20, and rotatably fitted to the circumferential portion 11 a of the base portion 11 (refer to FIGS. 2A and 2B). An outer circumferential portion 30 a of the intermediate knob 30 serves as a portion gripped by fingers during a knob operation that causes rotation. A cam portion 30 b corresponding to the cam portion 20 b of the cam 20 is formed on the cam 20 side of the intermediate knob 30. With the intermediate knob 30 and the cam 20 fitted together and integrated, a gap between this cam portion 30 b and the cam portion 20 b of the cam 20 forms a cam groove having a uniform width. The cam groove is an inclined groove that inclines with respect to the longitudinal axis CL, and this inclined groove to a drive pin 132 of the first movable contact member 130. The first movable contact member 130, as described later, is guided by the lever main body 10 and movable only in the longitudinal axis CL direction, and therefore is driven in the longitudinal axis CL direction by the rotational operation of the intermediate knob 30.

Bottomed holes 30 c that house the first springs 110 are formed inside the intermediate knob 30. Further, walls 30 f of these bottomed holes 30 c function as a regulating portion for restricting a rotational operation range with respect to the middle 40 (refer to FIGS. 4A and 4B). The first springs 110 allow the first balls 111 to be resiliently in contact with a detent peak portion of the middle 40. Further, a temporary assembly surface 30 d that comes into contact with the middle 40 upon assembly of the subassembly 100 is formed on the middle 40 side of the intermediate knob 30 (refer to FIG. 3).

Middle 40

The middle 40 is a fixed member that is fixed to the lever main body 10, supports the intermediate knob 30 or the cap 60 so that either is rotationally operable about the longitudinal axis CL, and that prevents the subassembly 100 from falling off the lever main body 10. The middle 40 is formed in a cylindrical shape, and an outer circumferential portion 40 a thereof has substantially the same diameter as those of the intermediate knob 30 and the cap 60 and displays explanations of functions executed by a rotational operation, such as a headlight symbol mark, AUTO, and the like. An inner circumference portion 40 b is fitted to the circumferential portion 11 a of the base portion 11, and a fixing catch portion 40 c is fitted to and locked by the locking hole 11 h of the lever main body 10, thereby fixing the middle 40 to the lever main body 10.

A detent peak portion 40 d for giving a detent feeling in association with a rotational operation upon contact by the first balls 111 is formed on the intermediate knob 30 side of the middle 40. Further, a boss portion 40 e including a temporary assembly surface 40 f that comes into contact with the intermediate knob 30 upon assembly of the subassembly 100 is formed.

As illustrated in FIG. 4B, the wall 30 f of the intermediate knob 30 comes into contact with the boss portion 40 e of the middle 40 by the rotational operation of the intermediate knob 30, thereby regulating the rotational operation range of the intermediate knob 30.

A middle stopper 40 g for regulating the rotational operation range of the cap 60 is formed so as to protrude on the distal end knob 50 side of the middle 40. Further, bottomed holes 40 h that house the second springs 120 are formed inside the middle 40. This allows the second balls 121 to be resiliently in contact with a detent peak portion of the distal end knob 50.

Distal End Knob 50

The distal end knob 50 is equivalent to the knob member. The distal end knob 50 is formed in a cylindrical shape that includes a cylindrical portion 50 a and a flange portion 50 b so as to be rotatably fitted to the circumferential portion 11 a of the base portion 11. A detent peak portion 50 c for giving a detent feeling in association with a rotational operation upon contact by the second balls 121 is formed on the middle 40 side of the distal end knob 50.

The flange portion 50 b includes a portion formed as a notched portion 50 d, and this notched portion 50 d has a width significantly larger than the width of the middle stopper 40 g. This makes it possible to pass the middle stopper 40 g through the notched portion 50 d of the flange portion 50 b, insert the distal end knob 50 into the middle 40, and rotate the distal end knob 50, causing a sliding surface 50 e formed on an end surface of the flange 50 b to come into contact with a sliding surface 40 j formed on a lower portion of the middle stopper 40 g illustrated in FIGS. 2A and 2B. That is, the sliding surface 40 j and the sliding surface 50 e function as rotation sliding surfaces in the direction of the longitudinal axis CL serving as the rotational axis when the distal end knob 50 (cap 60) is rotationally operated with respect to the middle 40 serving as the fixing portion.

A cam portion 50 f is formed on the cap 60 side of the distal end knob 50. This cam portion 50 f is formed with an inclined surface that inclines with respect to the longitudinal axis CL. Further, a locking catch portion 50 g for integrally fixing the distal end knob 50 with the cap 60 is formed at two locations, and a groove portion 50 h for fixing the distal end knob 50 so as to prevent relative rotation with the cap 60 is formed at two locations (refer to FIG. 2B).

Cap 60

The cap 60 is equivalent to the rotor member. The cap 60 is formed in a bottomed cylindrical cap shape, fitted and integrated with the cylindrical portion 50 a of the distal end knob 50, and rotatably fitted to the circumferential portion 11 a of the base portion 11. A fitting hole 60 b is formed on a distal end portion of a projection portion 60 a formed protruding from the inside of the cap 60, and engages with the locking catch portion 50 g of the distal end knob 50, thereby fixing the cap 60 to the distal end knob 50.

A cam portion 60 c corresponding to the cam portion 50 f of the distal end knob 50 is formed on the distal end knob 50 side of the cap 60. With the cap 60 and the distal end knob 50 integrated, a gap between this cam portion 60 c and the cam portion 50 f of the distal end knob 50 forms a cam groove having a uniform width. The cam groove is an inclined groove that inclines with respect to the longitudinal axis CL, and this inclined groove is fitted to a drive pin 142 of the second movable contact member 140. The second movable contact member 140, as described later, is guided by the lever main body 10 and movable only in the longitudinal axis CL direction, and therefore is driven in the longitudinal axis CL direction by the rotational operation of the cap 60.

A cap stopper 60 d is formed in the cylindrical interior of the cap 60, as illustrated in FIG. 2B. This cap stopper 60 d is fitted to the groove portion 50 h of the distal end knob 50, thereby integrally fixing the distal end knob 50 and the cap 60. Further, the cap stopper 60 d, which is the rotation regulating portion, comes into contact with a middle stopper surface 40 k, which is an end portion of the middle stopper 40 g and serves as the rotation regulating portion, by the rotational operation of the cap 60, thereby regulating the rotational operation range of the cap 60.

Flexible Substrate 70

The flexible substrate 70 includes a film substrate 71 and a rigid substrate 72. The film substrate 71 is obtained by forming a conductor foil of copper or the like formed in a predetermined circuit pattern on a base insulator of a film of polyimide or the like. Further, the rigid substrate 72 is a rigid substrate such as a glass epoxy substrate.

The film substrate 71 is lined with the rigid substrate 72 on a back side of the film substrate, in the movable range of the movable contact members (first movable contact member 130, second movable contact member 140). On the other hand, the flexible substrate 70 on the intermediate portion 13 and lever shaft portion 12 side of the lever main body 10 is only formed of a film substrate 71 that is not lined with the rigid substrate 72, making it possible to bend and route the flexible substrate 70 in accordance with the shape of the lever main body 10.

The signal contacts 71 a and the ground contact 71 b (common contact) are formed on the front side of the film substrate 71 so as to come into contact with the contact terminals (133, 143) of the movable contact members. Further, a pattern is exposed on each of the contacts so that the contacts can electrically come into contact with the contact terminals (133, 143). Other patterns and wiring portions, insulated by a coverlay, form patterns up to a connector end portion 71 c.

While a portion of the film substrate 71 of the flexible substrate 70 is disposed in the base portion 11 of the lever main body 10, the portion of the film substrate 70, which is disposed in the base portion 11, is lined with the rigid substrate 72, thereby causing the flexible substrate 70 to be linearly disposed, without bending, in the longitudinal axis CL direction in at least the movable range of the movable contact members (first movable contact member 130, second movable contact member 140).

As illustrated in FIG. 2A, the flexible substrate 70 includes a contact structure that becomes conductive or non-conductive by the signal contacts 71 a and the ground contact 71 b coming into contact with or separating from the contact terminals (133, 143). The ground contact 71 b is disposed on the lower side of the lever main body 10. The contact terminals (133, 143) electrically come into contact with the signal contacts 71 a or the ground contact 71 b (common terminal), making it possible to control the turning on and off of lights and the like in accordance with the contact combination.

Lever Cover 80

The lever cover 80 is inserted into the space portion 11 c in a direction of the arrow in FIG. 1 and mounted to the lever main body 10, thereby fixing the flexible substrate 70. Further, the lever cover 80 presses the film substrate 71 along the intermediate portion 13 and the lever shaft portion 12 of the lever main body 10 (refer to FIGS. 1 and 5). The lever cover 80 includes a main portion 81 that is inserted into the space portion 11 c of the lever main body 10 and mounted to the lever main body 10, and a bending portion 82 that bends on the intermediate portion 13 side.

As illustrated in FIG. 5, the flexible substrate 70 (film substrate 71 and rigid substrate 72) is fixed by the lever cover 80 while pressed against a contacting portion 11 j of the space portion 11 c of the lever main body 10.

The main portion 81 of the lever cover 80 includes the catch portion 81 a, a curved portion 81 b, and a projection portion 81 c for pressing the flexible substrate 70 against the contacting portion 11 j, as illustrated in the cross-sectional view of FIG. 5. The lever cover 80 is formed of a synthetic resin, and thus can elastically bend mainly at the curved portion 81 b. As a result, the catch portion 81 a is fitted to and locked by the locking hole 11 g of the lever main body 10 with the flexible substrate 70 pressed against the contacting portion 11 j by the projection portion 81 c.

It should be noted that the projection portion 81 c, as illustrated in FIG. 5, presses a substantially central portion of the substantially flexible substrate 70, and is formed at a plurality of locations in the longitudinal axis CL direction, causing the flexible substrate 70 to press against the contacting portion 11 j along a sliding direction of the movable contact members (first movable contact member 130, second movable contact member 140) as illustrated in FIG. 1. This makes it possible to support the flexible substrate so that the flexible substrate is linearly disposed in the longitudinal axis CL direction in the movable range of the movable contact members.

Upper Cover 90 and Lower Cover 91

An upper cover 90 and a lower cover 91 sandwich and cover the lever main body 10, the flexible substrate 70, the lever cover 80, and the like in an assembled state, in the direction of the arrow illustrated in FIG. 1. The upper cover 90 and the lower cover 91 are formed of a synthetic resin and are made to cover the lever main body 10 and the like at an end of an assembly process, functioning as cover members as well as design components.

First Movable Contact Member 130 and Second Movable Contact Member 140 The first movable contact member 130 and the second movable contact member 140, which serve as movable contact members, include movable bodies 131, 141, the drive pins 132, 142 formed protruding from the movable bodies, and the contact terminals 133, 143 that come into contact with the contact portions (signal contacts 71 a, ground contact 71 b), as illustrated in FIGS. 1 and 5. The first movable contact member 130 and the second movable contact member 140 are integrally formed with the contact terminals 133, 143 by insert molding using a synthetic resin, respectively.

It should be noted that materials used for the contact terminals 133, 143 include metals such as copper, phosphor bronze, beryllium copper, and the like.

The movable bodies 131, 141, as illustrated in FIG. 5, are housed in the long guide holes 11 e of the base portion 11, and are movable while sliding in the longitudinal axis CL direction. The drive pins 132, 142 that protrude from the movable bodies 131, 141 are respectively inserted into the cam groove formed by fitting and integrating the cam 20 with the intermediate knob 30, and the cam groove formed by integrating the distal end knob 50 with the cap 60.

As described above, these cam grooves are inclined grooves that incline with respect to the longitudinal axis CL, and thus a driving force in the longitudinal axis CL direction acts on the drive pins 132, 142 and the movable bodies 131, 141 by the rotational operation of the rotor members (cam 20, cap 60) or the knob members (intermediate knob 30, distal end knob 50) about the longitudinal axis CL. As a result, the contact terminals 133, 143 can move in the longitudinal axis CL direction while in contact with the surface of the film substrate 71 of the flexible substrate 70. That is, it is possible to control the turning on and off of lights and the like in accordance with the combination of contact between the signal contacts 71 a or the ground contact 71 b (common contact) and the contact terminals (133, 143) resulting from the rotational operation of the rotor members (cam 20, cap 60) or the knob members (intermediate knob 30, distal end knob 50) about the longitudinal axis CL.

Subassembly 100

The subassembly 100 illustrated in FIGS. 1 and 3 is obtained by temporarily assembling the intermediate knob 30, the middle 40, the distal end knob 50, as well as the first springs 110, the first balls 111, the second springs 120, and the second balls 121 serving as detent components into a single piece in a process before incorporation into the switch device 1.

The first springs 110 are housed in the respective bottomed holes 30 c of the intermediate knob 30. The intermediate knob 30 is incorporated into the middle 40 with the first balls 111 disposed in the distal end portions of the first springs 110.

A boss portion 40 e of the middle 40 is inserted into the intermediate knob 30 side and rotated, causing the temporary assembly surface 30 d of the intermediate knob 30 and the temporary assembly surface 40 f of the middle 40 to come into contact, as illustrated in FIGS. 3 and 4B. In this state, the resilient force of the first springs 110 causes the temporary assembly surface 40 f and the temporary assembly surface 30 d to come into contact with a constant spring force.

Further, the first balls 111 come into contact with the detent peak portion 40 d of the middle 40 with the spring force described above.

This causes a detent feeling (click feeling) to be felt when the intermediate knob 30 is rotationally operated. It should be noted that grease is applied to the first balls 111 and the detent peak portion 40 d.

In this temporarily assembled state, a gap between the intermediate knob 30 and the middle 40 is d₁, as illustrated in FIG. 3.

Next, the distal end knob 50 is incorporated into the middle 40. The second springs 120 are housed in the respective bottomed holes 40 h of the middle 40. The distal end knob 50 is incorporated in the middle 40 with the second balls 121 disposed in the distal end portions of the second springs 120. The middle stopper 40 g of the middle 40 is passed through the notched portion 50 d of the flange portion 50 b of the distal end knob 50, and the distal end knob 50 is inserted into the middle 40 and rotated, causing the sliding surface 40 j formed on the lower portion of the middle stopper 40 g illustrated in FIGS. 2A and 2B to come into contact with the sliding surface 50 e of the distal end knob 50. In this state, the resilient force of the second springs 120 causes the sliding surface 40 j of the middle 40 and the sliding surface 50 e of the distal end knob 50 to come into contact with a constant spring force.

This contacting surface serves as a sliding surface upon the rotational operation of the cap 60 (distal end knob 50) after assembly of the switch device 1.

Further, the second balls 121 come into contact with the detent peak portion 50 c of the distal end knob 50 with the spring force described above. This causes a detent feeling (click feeling) to be felt when the cap 60 (distal end knob 50) is rotationally operated. It should be noted that grease is applied to the second balls 121 and the detent peak portion 50 c.

As described above, the intermediate knob 30, the middle 40, the distal end knob 50, as well as the first springs 110, the first balls 111, the second springs 120, and the second balls 121 serving as detent components are temporarily assembled into a single piece in a process before incorporation into the switch device 1. This makes it possible to perform assembly in one direction of the longitudinal axis CL of the lever main body 10 in the assembly process of the switch device 1.

This also makes it possible to collectively apply grease to the first springs 110, the first balls 111, the second springs 120, and the second balls 121 serving as the detent components, which simplifies the grease application process, and shortens the work process.

Assembly of Switch Device 1

The following describes the assembly of the switch device 1 on the basis of FIG. 1.

First, the flexible substrate 70 is fixed to the base portion 11 of the lever main body 10. The flexible substrate 70 is inserted into the space portion 11 c of the base portion 11, and then the main portion 81 of the lever cover 80 is pressed in, thereby causing the catch portion 81 a to be fitted to and locked by the locking hole 11 g and the flexible substrate 70 and the lever cover 80 to be fixed. As a result, the flexible substrate is linearly disposed in the longitudinal axis CL direction in the movable range of the movable contact members.

Next, the cam 20 is incorporated into the base portion 11 of the lever main body 10. The cam 20 is inserted until being in contact with the flange portion 11 d of the base portion 11.

The first movable contact member 130 is passed through the incorporation hole 11 f of the base portion 11 and inserted into the long guide hole 11 e.

The subassembly 100 is inserted into the base portion 11 of the lever main body 10 and pressed until being fitted to the cam 20. As a result, the fixing catch portion 40 c of the middle 40 is fitted to and locked by the locking hole 11 h of the lever main body 10, thereby fixing the middle 40 to the lever main body 10. That is, the subassembly 100 is mounted to the base portion 11 of the lever main body 10.

With the subassembly 100 incorporated into the base portion 11, a distance from an end surface of the flange portion 11 d to an end surface of the fixing catch portion 40 c is a predetermined value d₀, as illustrated in FIGS. 2A and 2B. At this time, the first springs 110 are slightly compressed, causing the gap d₁ between the intermediate knob 30 and the middle 40 in a temporarily assembled state to become a setting value d₀₁ in the fully assembled state (refer to FIGS. 2A, 2B, and 3). The setting value d₀₁ after this assembly is less than the gap d₁ in the temporary assembled state. The setting value d₀₁ after assembly is set to, for example, 0.3 mm. Further, the state of contact between the temporary assembly surface 40 f of the middle 40 and the temporary assembly surface 30 d of the intermediate knob 30 upon temporary assembly is released, forming a gap between the temporary assembly surface 40 f and the temporary assembly surface 30 d. This makes the intermediate knob 30 (cam 20) smoothly rotationally operable around the circumferential portion 11 a of the base portion 11.

Next, the second movable contact member 140 is passed through the incorporation hole 11 f of the base portion 11 and inserted into the long guide hole 11 e.

The cap 60 is inserted into the base portion 11 of the lever main body 10, and the cap 60 is fitted and fixed to the distal end knob 50. This makes the cap 60 (distal end knob 50) smoothly rotationally operable around the circumferential portion 11 a of the base portion 11 while the sliding surface 40 j of the middle 40 is in contact with the sliding surface 50 e of the distal end knob 50.

Lastly, the upper cover 90 and the lower cover 91 sandwich and fix the lever main body 10 assembled as described above. With this, the assembly process of the switch device 1 is completed.

In the assembly process described above, the portion of the flexible substrate 70 that is lined with the rigid substrate 72 is assembled to the base portion 11 of the lever main body 10, making a bending process unnecessary and allowing the flexible substrate 70 to be easily linearly disposed in the longitudinal axis CL direction in the movable range of the movable contact members (first movable contact member 130, second movable contact member 140). The other processes are also processes in which the members are simply sequentially disposed, thereby making automatic assembly possible. It should be noted that the upper cover 90 and the lower cover 91 are design components, and therefore may be assembled in a separate process after automatic assembly.

Effect of Embodiment(s) of Present Invention

According to the embodiment of the present invention, the cap stopper 60 d, which is the rotation regulating portion, comes into contact with the middle stopper surface 40 k, which is an end portion of the middle stopper 40 g and serves as the rotation regulating portion, by the rotational operation of the cap 60, thereby regulating the rotational operation range of the cap 60 (distal end knob 50).

Meanwhile, the sliding surface 50 e formed on the end surface of the flange portion 50 b is made to come into contact with the sliding surface 40 j formed on the lower portion of the middle stopper 40 g serving as the rotation regulating portion illustrated in FIGS. 2A and 2B. That is, the sliding surface 40 j and the sliding surface 50 e function as rotation sliding surfaces in the direction of the longitudinal axis CL serving as the rotational axis when the distal end knob 50 (cap 60) is rotationally operated with respect to the middle 40 serving as the fixing portion.

With such a configuration, the rotation regulating portion (e.g., the middle stopper surface 40 k) that regulates the rotatable range of the knob member (distal end knob 50) with respect to the middle 40, and the rotation sliding surface (e.g., the sliding surface 40 j) in the rotational axis (longitudinal axis CL) direction of the middle 40 and the knob member (distal end knob 50) are integrated.

As a result, it is possible to provide a switch device having excellent design flexibility even in a limited space. Specifically, it is possible to arrange a structure integrally including the sliding surface and the rotation regulating portion on an outer side of a mechanism, and arrange the movable contact member or the like operated in the longitudinal axis CL direction on an inner side of the mechanism.

Although embodiments of the present invention have been described above, these embodiments are merely examples and the invention according to claims is not to be limited thereto. Novel embodiments and modifications thereof may be implemented in various other forms, and various omissions, substitutions, changes, and the like can be made without departing from the spirit and scope of the present invention. In addition, all combinations of the features described in these embodiments are not necessary to solve the problem of the invention. Further, these embodiments and modifications are included within the spirit and scope of the invention and also within the invention described in the claims and the scope of equivalents thereof.

REFERENCE SIGNS LIST

-   1 Switch device -   10 Lever main body -   11 Base portion -   11 a Circumferential portion -   11 b Flat portion -   11 c Space portion -   11 d Flange portion -   11 e Long guide hole -   11 f Incorporation hole -   11 g Locking hole -   11 h Locking hole -   11 j Contacting portion -   12 Lever shaft portion -   13 Intermediate portion -   20 Cam (rotor member) -   20 a End surface -   20 b Cam portion -   20 c Projection portion -   30 Intermediate knob (knob member) -   30 a Outer circumferential portion -   30 b Cam portion -   30 c Bottomed hole -   30 d Temporary assembly surface -   30 e Fitting recess portion -   30 f Wall -   40 Middle -   40 a Outer circumferential portion -   40 b Inner circumferential portion -   40 c Fixing catch portion -   40 d Detent peak portion -   40 e Boss portion -   40 f Temporary assembly surface -   40 g Middle stopper -   40 h Bottomed hole -   40 j Sliding surface -   40 k Middle stopper surface -   50 Distal end knob (knob member) -   50 a Cylindrical portion -   50 b Flange portion -   50 c Detent peak portion -   50 d Notched portion -   50 e Sliding surface -   50 f Cam portion -   50 g Locking catch portion -   50 h Groove portion -   60 Cap (rotor member) -   60 a Projection portion -   60 b Fitting hole -   60 c Cam portion -   60 d Cap stopper -   70 Flexible substrate -   71 Film substrate -   71 a Signal contact -   71 b Ground contact -   71 c Connector end portion -   72 Rigid substrate -   80 Lever cover -   81 Main portion -   81 a Catch portion -   81 b Curved portion -   81 c Projection portion -   82 Bending portion -   90 Upper cover -   91 Lower cover -   100 Subassembly -   110 First spring -   111 First ball -   120 Second spring -   121 Second ball -   130 First movable contact member -   131, 141 Movable body -   132, 142 Drive pin -   133, 143 Contact terminal -   140 Second movable contact member -   200 Water droplet -   CL Longitudinal axis 

What is claimed is:
 1. A switch device comprising: a knob member rotatably fitted to and supported by a fixing portion; and a rotor member integrally mounted to the knob member and rotatably supported by the fixing portion, wherein a rotation regulating portion that regulates a rotatable range of the knob member with respect to the fixing portion, and a rotation sliding surface in a rotational axis direction of the fixing portion and the knob member are collectively formed.
 2. The device according to claim 1, wherein the rotation sliding surface of the fixing portion is formed on a lower portion of the rotation regulating portion of the fixing portion.
 3. The device according to claim 1, wherein the rotation sliding surface of the knob member is formed on an end surface of a flange portion of the knob member.
 4. A switch device, comprising: a knob member rotatably around a rotational axis fitted to and supported by a fixing portion; and a rotor member integrally mounted to the knob member and rotatably around the rotational axis supported by the fixing portion, wherein the fixing portion comprises a rotation regulating portion that regulates a rotatable range of the rotor member, and a rotation sliding surface that contacts with the knob member when the rotor member is rotated with respect to the fixing member.
 5. The device according to claim 4, wherein the rotation regulating portion comprises a contact surface formed substantially in a radial direction of the rotational axis, and wherein the contact surface is substantially orthogonal to the rotation sliding surface.
 6. The device according to claim 4, wherein the rotation regulating portion and the rotation sliding surface are formed outside the knob member in a radial direction of the rotational axis. 